English

Cutoff phenomena for random walks on random regular graphs

Probability 2019-12-19 v2 Combinatorics

Abstract

The cutoff phenomenon describes a sharp transition in the convergence of a family of ergodic finite Markov chains to equilibrium. Many natural families of chains are believed to exhibit cutoff, and yet establishing this fact is often extremely challenging. An important such family of chains is the random walk on \G(n,d)\G(n,d), a random dd-regular graph on nn vertices. It is well known that almost every such graph for d3d\geq 3 is an expander, and even essentially Ramanujan, implying a mixing-time of O(logn)O(\log n). According to a conjecture of Peres, the simple random walk on \G(n,d)\G(n,d) for such dd should then exhibit cutoff with high probability. As a special case of this, Durrett conjectured that the mixing time of the lazy random walk on a random 3-regular graph is w.h.p. (6+o(1))log2n(6+o(1))\log_2 n. In this work we confirm the above conjectures, and establish cutoff in total-variation, its location and its optimal window, both for simple and for non-backtracking random walks on \G(n,d)\G(n,d). Namely, for any fixed d3d\geq3, the simple random walk on \G(n,d)\G(n,d) w.h.p. has cutoff at dd2logd1n\frac{d}{d-2}\log_{d-1} n with window order logn\sqrt{\log n}. Surprisingly, the non-backtracking random walk on \G(n,d)\G(n,d) w.h.p. has cutoff already at logd1n\log_{d-1} n with constant window order. We further extend these results to \G(n,d)\G(n,d) for any d=no(1)d=n^{o(1)} that grows with nn (beyond which the mixing time is O(1)), where we establish concentration of the mixing time on one of two consecutive integers.

Keywords

Cite

@article{arxiv.0812.0060,
  title  = {Cutoff phenomena for random walks on random regular graphs},
  author = {Eyal Lubetzky and Allan Sly},
  journal= {arXiv preprint arXiv:0812.0060},
  year   = {2019}
}

Comments

33 pages, 4 figures

R2 v1 2026-06-21T11:46:36.972Z